Matthew S.P. Ho

Nidogens-extracellular matrix linker molecules

Nidogens/entactins are a family of highly conserved, sulfated glycoproteins. Biochemical studies have implicated them as having a major structural role in the basement membrane. However despite being ubiquitous components of this specialized extracellular matrix and having a wide spectrum of binding partners, genetic analysis has shown that they are not required for the overall architecture of the basement membrane. Rather in development they play an important role in its stabilization especially in tissues undergoing rapid growth or turnover. Nidogen breakdown has been implicated as a key event in the basement membrane degradation occurring in mammary gland involution. A number of studies, most compellingly those in C. elegans, demonstrated that nidogens may have other nonstructural roles and be involved in axonal pathfinding and synaptic transmission. Microsc. Res. Tech., 2008.

A synaptic nidogen: Developmental regulation and role of nidogen-2 at the neuromuscular junction

BackgroundThe skeletal neuromuscular junction is a useful model for elucidating mechanisms that regulate synaptogenesis. Developmentally important intercellular interactions at the neuromuscular junction are mediated by the synaptic portion of a basal lamina that completely ensheaths each muscle fiber. Basal laminas in general are composed of four main types of glycosylated proteins: laminins, collagens IV, heparan sulfate proteoglycans and nidogens (entactins). The portion of the muscle fiber basal lamina that passes between the motor nerve terminal and postsynaptic membrane has been shown to bear distinct isoforms of the first three of these. For laminins and collagens IV, the proteins are deposited by the muscle; a synaptic proteoglycan, z-agrin, is deposited by the nerve. In each case, the synaptic isoform plays key roles in organizing the neuromuscular junction. Here, we analyze the fourth family, composed of nidogen-1 and -2.ResultsIn adult muscle, nidogen-1 is present throughout muscle fiber basal lamina, while nidogen-2 is concentrated at synapses. Nidogen-2 is initially present throughout muscle basal lamina, but is lost from extrasynaptic regions during the first three postnatal weeks. Neuromuscular junctions in mutant mice lacking nidogen-2 appear normal at birth, but become topologically abnormal as they mature. Synaptic laminins, collagens IV and heparan sulfate proteoglycans persist in the absence of nidogen-2, suggesting the phenotype is not secondary to a general defect in the integrity of synaptic basal lamina. Further genetic studies suggest that synaptic localization of each of the four families of synaptic basal lamina components is independent of the other three.ConclusionAll four core components of the basal lamina have synaptically enriched isoforms. Together, they form a highly specialized synaptic cleft material. Individually, they play distinct roles in the formation, maturation and maintenance of the neuromuscular junction.

Altered thalamocortical rhythmicity in Cav2.3-deficient mice

Voltage-gated calcium channels (VGCCs) are key regulators of neuronal excitability and important factors in epileptogenesis and neurodegeneration. Recent findings suggest a novel, important proictogenic and proneuroapoptotic role of the Ca(v)2.3 E/R-type VGCCs in convulsive generalized tonic-clonic and hippocampal seizures. Though Ca(v)2.3 is also expressed in key structures of the thalamocortical circuitry, their functional relevance in non-convulsive absence seizure activity remains unknown. To this end, we investigated absence specific spike-wave discharge (SWD) susceptibility in control and Ca(v)2.3-deficient mice by systemic administration of gamma-hydroxybutyrolactone (GBL, 70 mg/kg i.p.), followed by electrocorticographic radiotelemetric recordings, behavioral analysis and histomorphological characterization. Based on motoric studies, SWD and power-spectrum density (PSD) analysis, our results demonstrate that Ca(v)2.3(-/-) mice exhibit increased absence seizure susceptibility and altered absence seizure architecture compared to control animals. This study provides evidence for the first time that Ca(v)2.3 E/R-type Ca2+ channels are important in modulating thalamocortical hyperoscillation exerting anti-epileptogenic effects in non-convulsive absence seizures.

Basement membrane protein nidogen-1 shapes hippocampal synaptic plasticity and excitability.

The basement membrane (BM) is a specialized form of extracellular matrix (ECM) underlying epithelia and endothelia and surrounding many types of mesenchymal cells. Nidogen, along with collagen IV and laminin, is a major component of BMs. Although certain ECM proteins such as laminin or reelin influence neuronal function via interactions with cell‐surface receptors such as integrins, behavioral neurological impairments due to deficits of BM components have been recognized only recently. Here, alterations in neuronal network function underlying these behavioral changes are revealed. Using nidogen‐1 knockout mice, with or without additional heterozygous nidogen‐2 knockout (NID1−/−/NID2+/+ or NID1−/−/NID2±), we demonstrate that nidogen is essential for normal neuronal network excitability and plasticity. In nidogen‐1 knockouts, seizurelike behavior occurs, and epileptiform spiking was seen in hippocampal in vivo EEG recordings. In vitro, hippocampal field potential recordings revealed that lack of nidogen‐1, while not causing conspicuous morphological changes, led to the appearance of spontaneous and evoked epileptiform activity, significant increase of the input/output ratio of synaptically evoked responses in CA1 and dentate gyrus, as well as of paired pulse accentuation, and loss of perforant‐path long‐term synaptic potentiation. Nidogen‐1 is thus essential for normal network excitability and plasticity.

Nidogen and Nidogen-Associated Basement Membrane Proteins and Neuronal Plasticity

Extracellular matrix (ECM) proteins are thought to subserve structural functions as, for example, tissue barriers as well as guidance structures during cell growth, differentiation and tissue repair. Deletion of basement membrane (BM) components results in malformations of different organs, including the brain. Recent data, however, suggest that interference with cellular membrane-associated proteins interacting with ECM can alter neuronal excitability and synaptic plasticity without obvious underlying structural damage. This does not only apply to classical ECM proteins such as laminin, reelin and tenascin, but also to molecules of a rather specialized ECM, the BM. Here, nidogen (also termed entactin) appears to subserve a function in neuronal plasticity. Nidogen ablation leads to epileptic activity in vivo and the appearance of spontaneous epileptiform activity in vitro. This raises the intriguing question whether the BM protein nidogen may directly influence neuronal function in the CNS, opening the possibility of modulatory mechanisms of synaptic plasticity and excitability reaching beyond classical processes confined to cellular interactions.

Retinal localization of the glutamate receptor GluR2 and GluR2-regulating proteins in diabetic rats.

Impaired glutamatergic activity and synaptic dysfunction contributing to excitotoxicity and neuronal degeneration has been observed in the diabetic retina. Here we analyzed the expression changes and trafficking abnormalities of the AMPA glutamate receptor 2 subunit (GluR2) and its regulators protein kinase Calpha (PKCalpha) and PKC-interacting protein 1 (PICK1) in the rat retina during the early phases of streptozotocin-(STZ-) induced diabetes. Diabetes was induced in Long Evans rats by injection of STZ. Two and six weeks after induction of diabetes, immunohistochemistry and in situ hybridization were performed on retinal paraffin sections to investigate the expression and localization of GluR2 and its regulators PKCalpha and PICK1. The cellular distribution and trafficking of these proteins in retinae were also investigated by subcellular fractionation and western blotting. While no significant changes were observed for GluR2 transcripts, we observed a strong increase in GluR2 immunoreactivity, predominantly in the ganglion cell layer (GCL) and the inner plexiform layer (IPL), as early as two weeks of diabetes. GluR2/3 immunoreactivity was further increased from the GCL to OPL after 6 weeks of diabetes. Increased expression of a phosphorylated non-synaptic population of GluR2 was detected in the GCL, the IPL and in distinct photoreceptor cells within the outer nuclear layer (ONL) of diabetic animals. Further, the PICK1 retinal distribution was unchanged two and six weeks after onset of diabetes and in both control and diabetic rat retinae the PKCalpha immunoreactivity remained the same. However, phosphorylated PKCalpha immunoreactivity was increased in diabetic retina as compared to control and peaked after 6 weeks of diabetes. Activated PKCalpha was almost completely lost in all membrane fractions and primarily recovered in the cytosolic fraction. These results are consistent with PKCalpha being re-localized in the diabetic retina. The observations indicate a diabetes-dependent increase in the activation of PKCalpha and a disturbed GluR2 regulation by altered internalization and recycling.

Atropine-sensitive hippocampal theta oscillations are mediated by Cav2.3 R-type Ca2+ channels

Hippocampal theta oscillations are key elements in numerous behavioral and cognitive processes. Based on the dualistic theory of theta oscillations, one can differentiate between atropine-sensitive and atropine-insensitive theta subtypes. Urethane-induced atropine-sensitive theta oscillations are driven by muscarinic signal transduction pathways through G protein q/11 alpha subunit (Gα(q/11)), phospholipase β( ¼) (PLCβ( ¼), inositol trisphosphate (InsP₃), diacylglycerole (DAG), and protein kinase C (PKC). Recent findings illustrate that Ca(v)2.3 Ca²⁺ channels are important targets of muscarinic signaling in the hippocampus mediating plateau potential generation, epileptiform burst activity, and complex rhythm generation in the septohippocampal network. To investigate the physiological implications of Ca(v)2.3 Ca²⁺ channels in hippocampal theta oscillations we performed radiotelemetric intrahippocampal (cornu ammonis (CA1)) recordings in urethane (800 mg/kg, i.p.) and atropine (50 mg/kg, i.p.) treated Ca(v)2.3⁺/⁺ and Ca(v)2.3⁻/⁻ mice followed by wavelet analysis of EEG data. Our results demonstrate that Ca(v)2.3 ablation, unlike PLCβ₁ deletion, does not result in complete abolishment of urethane-induced theta oscillations and that both mean and total theta duration is not significantly inhibited by subsequent atropine treatment, indicating that Ca(v)2.3 Ca²⁺ channels are important mediators of atropine-sensitive theta. Although theta frequency remained unchanged between both genotypes, the temporal characteristics of theta distribution, that is, theta architecture were significantly affected by the loss of Ca(v)2.3 Ca²⁺ channels. Our data suggest, for the first time, that Ca(v)2.3 voltage-gated Ca²⁺ channels (VGCC) are an important factor in septohippocampal synchronization associated with theta oscillation.